Review Article MEMS-Reconfigurable Metamaterials

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Apr 30, 2014 - Review Article. MEMS-Reconfigurable Metamaterials and Antenna Applications ... beam steering without the need for a beam-forming network.
Hindawi Publishing Corporation International Journal of Antennas and Propagation Volume 2014, Article ID 138138, 8 pages http://dx.doi.org/10.1155/2014/138138

Review Article MEMS-Reconfigurable Metamaterials and Antenna Applications Tomislav Debogovic1 and Julien Perruisseau-Carrier2 1

Laboratory of Electromagnetics and Acoustics, Ecole Polytechnique F´ed´erale de Lausanne (EPFL), EPFL-STI-IEL-LEMA, ELB 030 (Bˆatiment ELB), Station 11, 1015 Lausanne, Switzerland 2 Group for Adaptive MicroNanoWave Systems, Ecole Polytechnique F´ed´erale de Lausanne (EPFL), EPFL-STI-IEL-GR-JPC, ELB 030 (Bˆatiment ELB), Station 11, 1015 Lausanne, Switzerland Correspondence should be addressed to Tomislav Debogovic; [email protected] Received 27 February 2014; Accepted 22 March 2014; Published 30 April 2014 Academic Editor: Giacomo Oliveri Copyright © 2014 T. Debogovic and J. Perruisseau-Carrier. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited. This paper reviews some of our contributions to reconfigurable metamaterials, where dynamic control is enabled by microelectromechanical systems (MEMS) technology. First, we show reconfigurable composite right-/left-handed transmission lines (CRLHTLs) having state of the art phase velocity variation and loss, thereby enabling efficient reconfigurable phase shifters and leaky-wave antennas (LWA). Second, we present very low loss metasurface designs with reconfigurable reflection properties, applicable in reflectarrays and partially reflective surface (PRS) antennas. All the presented devices have been fabricated and experimentally validated. They operate in X- and Ku-bands.

1. Introduction Metamaterials [1–5] allow efficient manipulation of guided and free-space electromagnetic waves, thereby potentially improving existing and enabling novel microwave component and antenna designs [6–11]. On the other hand, dynamic reconfiguration [12–17] has become a prime need in modern communication and sensing systems, for instance, to scan space and polarization, to dynamically compensate for varying system conditions thereby guaranteeing optimal performance in real time, or to support a higher number of functionalities through a single and compact device. In this context, the implementation of reconfigurable metamaterials [18, 19] for antenna applications has become a topic of intense practical relevance. For example, reconfigurable metamaterials can enable operating frequency reconfiguration [13, 20], beam steering without the need for a beam-forming network [16, 21], and dynamic beamwidth control [22, 23]. The technology used to enable reconfiguration has a profound impact on the performance of reconfigurable metamaterials and consequently on the quality of microwave components and antennas utilizing them. Microelectromechanical systems (MEMS) technology [24–30] can provide excellent properties thanks to very low loss, virtually zero power

consumption (electrostatic control), high linearity, and possibility of monolithic integration. In this paper, we show reconfigurable metamaterial devices with direct applications in antenna systems. In Section 2, we present a Ku-band MEMS-reconfigurable composite right-/left-handed transmission lines (CRLH-TLs) with applications in leaky-wave antennas (LWA) and feed networks for antenna arrays. In Section 3, we present X-band MEMS-reconfigurable metasurfaces whose reflection properties can be reconfigured. These devices can be applied for dynamic beam-scanning/-forming in reflectarrays and dynamic beamwidth control in partially reflective surface (PRS) antennas. The underlying reconfiguration technology is MEMS due to the need for low loss, convenient control, and ability to monolithically integrate a large number of controlling elements into an electrically large structure. Finally, conclusions are drawn in Section 4.

2. MEMS-Reconfigurable CRLH-TLs A composite CRLH-TL structure [4, 5, 31–33] is a class of 1-D metamaterial, which can be implemented by lumped “dual” elements (series capacitors 𝐶𝑠 and shunt inductors 𝐿 𝑝 )

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loading a usual TL, as shown in Figure 1(a). It is interesting because it can provide both positive and negative phase shifts, corresponding to the left-handed and right-handed region of the Bloch-Floquet propagation constant, respectively, with seamless transition between them. In addition, it is inherently wideband structure, thereby being well suited for low loss phase shifting and antenna applications. MEMS technology enables relatively straightforward phase shift reconfiguration by dynamically controlling the series capacitance 𝐶𝑠 [34, 35] or both series capacitance 𝐶𝑠 and shunt inductance 𝐿 𝑝 [36]. One possible unit cell design, implementing the circuit model of Figure 1(a), is shown in Figure 1(b) [34]. A similarly operating design can be found in [35] as well. Series MEMS capacitors and folded shunt stub inductors load a coplanar waveguide (CPW) line. The profile of the MEMS area is shown in the inset of Figure 1(b). The bottom MEMS electrode is a part of the CPW signal line in the middle of the unit cell, and it is dc grounded through inductive stubs. The movable MEMS membrane, essentially operating as the series capacitor 𝐶𝑠 , is connected to the CPW signal line at the unit cell input/output by the main anchor. Electrostatic MEMS actuation, enabling analog capacitance control, is achieved by applying a voltage between CPW signal line and grounds at

the cell input/output. Several unit cells can be cascaded by using dc-block capacitors and high resistivity bias lines. The unit cell was fabricated using MEMS process developed at Middle East Technical University on 500 𝜇m thick glass wafers, detailed in [27]. Simulated propagation constant 𝛾𝐵 (without MEMS actuation) is shown in Figure 2(a). A typical CRLH-TL dispersion is observed, with the frequency of the 0∘ phase shift (corresponding to the transition between the left- and righthanded bands) at 𝑓0 = 14 GHz. Simulated and measured results of the transmission phase upon reconfiguration are shown in Figure 2(b). Reconfigurable CRLH-TLs have at least two applications in antennas, both based on the transmission phase manipulation shown in Figure 2(b). The first one concerns leaky-wave antennas scanning around broadside [4, 5, 7] and it relies on the ability to generate a reconfigurable negative/zero/positive phase shift at a given operating frequency, as symbolized by the “A” arrow in the figure. The second main application concerns series feed networks or dividers [4, 5]. These devices operate at the frequency of 0∘ phase shift. Thus, their frequency of 0∘ phase shift 𝑓0 , in fact, their operating frequency, could be reconfigured as shown by the “B” arrow in Figure 2(b). Owing to the MEMS technology,

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very low insertion loss is achieved, being less than 0.7 dB when the transmission phase is reconfigured and less than 0.8 dB when the frequency of 0∘ phase shift is reconfigured. A differential phase shift over losses is 38∘ /dB at 14 GHz. Apart from the analog MEMS control presented above, digital MEMS control (where MEMS elements take two discrete states, namely, “up” and “down”) can also be implemented. In fact, this type of control is less sensitive to MEMS fabrication tolerances and vibrations, and nowadays it is widely accepted. A CRLH-TL unit cell with digital MEMS control [36] is shown in Figure 3. A digital MEMS capacitor located in the horizontal CPW line acts as the series capacitor, while the remaining two (identical) MEMS elements, located in the vertical shorted CPW stubs, serve to effectively change their length and hence the shunt inductance value. As a result, a CRLH-TL line with the phase shift of −50∘ /+50∘ is obtained.

3. MEMS-Reconfigurable Metasurfaces This section presents unit cells of two MEMS-reconfigurable metasurface types. The first type is designed to provide reflection phase reconfiguration and it has direct application in reconfigurable reflectarray antennas [17], where shaping of reflection phase profile of a reflector allows dynamic beamscanning. Such functionality and essentially flat reflectarray antenna geometry are very useful in space communications and radars. The second metasurface type presented is a partially reflective (or a partially transparent) design whose reflection magnitude can be reconfigured owing to the embedded MEMS elements. Placing such a metasurface approximately half a wavelength above a source antenna backed by a ground plane results in a reconfigurable partially reflective surface (PRS) antenna [37], whose directivity (beamwidth) depends on the metasurface reflectivity. Therefore, directivity and

Figure 3: Digitally controlled MEMS-based CRLH-TL unit cell from [36]. Series capacitance and shunt inductances are controlled in two discrete states.

beamwidth of such an antenna can be dynamically controlled by the MEMS elements. This functionality is useful for instance in satellite communications from elliptical orbits, where the antenna coverage should remain constant despite variable platform altitude. 3.1. Metasurface Unit Cell with Reflection Phase Control. Figure 4 shows the reconfigurable reflection phase metasurface unit cell [38]. In essence, it is a tunable resonator that consists of two pseudorings backed by a ground plane and loaded by digital series MEMS capacitors. As the structure is backed by the ground plane, its reflection loss is only a subject to the dissipation in the materials and MEMS elements, being generally very low. The MEMS elements are organized in five pairs in order to retain symmetry and thereby lower the crosspolarization level. The resonance is tuned by altering the capacitance values of the MEMS pairs. This implies that the metasurface reflection phase can be reconfigured in 25 = 32 discrete states at a given operating frequency. The metasurface reflection phase values for all 32 combinations of the MEMS states are shown in Figure 5. It can be

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noticed that the reflection phase can be reconfigured within full 360∘ range. In addition, the phase curves at the limits of 5% bandwidth are quasi-parallel to the one observed at the operating frequency, as required to avoid beam squint in a reconfigurable reflectarray [39]. The observed reflection loss is very low, mainly below 0.3 dB. The main design effort in such metasurfaces is to obtain the uniform phase step between MEMS states and to retain it in a given bandwidth, while also keeping the phase range close to 360∘ and loss as small as possible. This is a matter of a compromise, but it can be nearly achieved by employing an optimization routine developed in [40], where full-wave simulation results are combined with postprocessing data [41] in order to fulfill the desired goal. The fabrication process of this unit cell is based on the deposition of a 500 nm thick gold layer and a 1500 nm thick aluminum one on a quartz substrate [42]. It includes the possibility to pattern high-resistivity polysilicon bias lines which do not impact on the microwave performance, which is a very important feature when designing MEMS-based metamaterials. 3.2. Metasurface Unit Cell with Reflection Magnitude Control. Figure 6 shows the layout and photography of the reconfigurable reflection magnitude metasurface unit cell [43].

The unit cell topology is based on a ring-like shape, loaded by digital series MEMS capacitors 𝑆𝑥 and 𝑆𝑦 . The MEMS elements come by pairs to preserve symmetry. Owing to this property, the MEMS pairs 𝑆𝑥 and 𝑆𝑦 affect reflection properties independently in 𝑥- and 𝑦-polarizations, respectively, thereby enabling a 1-bit dual-polarization operation. This unit cell is fabricated by RF Microtech using the process described in [44]. It also includes the possibility to pattern highresistivity polysilicon bias lines which do not impact on the microwave performance (visible in Figure 6(a) as narrow lines). The unit cell reflection coefficient is shown in Figure 7(a), for incident 𝑥-polarization at the design frequency 𝑓0 = 11.2 GHz. The reflection magnitude in this polarization is controlled (in two discrete states) by the MEMS pair 𝑆𝑥 and independent of the states of the MEMS pair 𝑆𝑦 . As the metasurface is practically lossless and single-layered, the reflection magnitude reconfiguration implies a reflection phase variation as well. However, in a properly assembled reconfigurable PRS antenna, the amplitude reconfiguration has a stronger impact [23]. Predicted radiation patterns of the assembled PRS antenna, formed by placing such a metasurface above a source antenna (and thereby creating a Fabry-P´erot resonator) are shown in Figure 7(b). It can be noticed that the antenna beamwidth is reconfigured in two discrete states by MEMS elements. Since the result is shown for the 𝑥-polarization, only the MEMS elements 𝑆𝑥 affect the beamwidth. Thanks to the MEMS technology and the unit cell design, the predicted radiation efficiency is above 75%, which is considered to be very high for a reconfigurable antenna operating in X-band. Results for the 𝑦-polarization are not shown here for space consideration, but they are essentially the same owing to the unit cell symmetry. Reflection measurement results [43] are shown in Figure 8. An orthomode transducer (OMT) was employed for this measurement. Being a square waveguide with couplers designed to separate its orthogonally polarized modes, the OMT allows validation of the unit cell reflectivity in two orthogonal linear polarizations. A very good agreement between measurements and simulations is observed, both in magnitude and phase, thereby validating the unit cell design and confirming the predicted reconfigurable PRS antenna performance. The main design effort concerning such metasurfaces is to obtain a considerable reflection magnitude range while keeping the loss as low as possible. This can be achieved at the unit cell level. Then, owing to the modelling procedure developed by authors [45], the whole PRS antenna simulation can be performed accurately and rapidly despite potentially large electrical size of the metasurface.

4. Conclusion Monolithic MEMS integration enables structures to have a potentially large number of embedded MEMS elements, at a price that does not depend directly on their number. This property, combined with other advantages of MEMS

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technology, such as extremely low power consumption, linearity, and availability of highly resistive bias lines, makes large reconfigurable 1-D and 2-D metamaterial designs with hundreds or even thousands of MEMS elements feasible. The main limitation of this technology lies in the actuation speed which is typically in the range of microseconds. MEMS-reconfigurable metamaterials, if properly designed, can bring valuable improvements to antenna systems, which was demonstrated in this paper. In Section 2, efficient MEMS-based CRLH-TLs were presented. It was shown that they can enable leaky-wave antennas with dynamic beam-scanning and improved array feed networks. In Section 3, MEMS-based metasurface designs with reconfigurable reflection properties were presented. Their utilization in reflectarrays and PRS antennas, resulting in dynamic radiation pattern control (beam-scanning and beamwidth reconfiguration), was discussed and demonstrated. These functionalities are welcome in radar systems and space communications. Current trends within the area of reconfigurable metamaterials for antenna applications are mainly oriented toward higher operating frequencies. MEMS technology can already be considered as a mature technology, with prominent properties up to mm wave frequencies. Emerging new technologies such as electrically actuated elastomers [46, 47], liquid crystals [48, 49], and graphene [50, 51] promise good reconfigurable antenna solutions at higher frequencies, up to terahertz bands.

Conflict of Interests The authors declare that there is no conflict of interests regarding the publication of this paper.

Acknowledgment This work was supported by the Swiss National Science Foundation (SNSF) under Grant no. 133583.

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